Step 1: Calculating Intrinsic Impedance of Medium B
The intrinsic impedance \( Z \) of a medium is defined as:
\[ Z = \sqrt{\frac{\mu}{\epsilon}} \] Where \( \mu = \mu_0 \mu_r \) and \( \epsilon = \epsilon_0 \epsilon_r \).
For material B, the intrinsic impedance \( Z_B \) is:
\[ Z_B = 377 \times \sqrt{\frac{4}{9}} = 377 \times \frac{2}{3} = 251.33 \, \Omega \] Therefore, the intrinsic impedance of medium B is approximately \( 251.33 \, \Omega \), corresponding to option B \( 80\pi \, \Omega \).
Step 2: Determining the Reflection Coefficient
The reflection coefficient \( R \) is given by:
\[ R = \frac{Z_2 - Z_1}{Z_2 + Z_1} \] Where \( Z_1 = Z_A = 188.5 \, \Omega \) and \( Z_2 = Z_B = 251.33 \, \Omega \).
\[ R = \frac{251.33 - 188.5}{251.33 + 188.5} = 0.143 \] Hence, the reflection coefficient is approximately 0.143, which aligns with option C \( \frac{1}{7} \).
Step 3: Finding the Transmission Coefficient
The transmission coefficient \( T \) is calculated as:
\[ T = 1 + R = 1 + 0.143 = 1.143 \] Thus, the transmission coefficient is 1.143, corresponding to option D \( \frac{8}{7} \).
Step 4: Computing the Phase Shift Constant of Medium B
The phase shift constant \( \beta \) is given by:
\[ \beta = \omega \sqrt{\mu \epsilon} \] For medium B, the phase shift constant \( \beta_B \) is:
\[ \beta_B = 6\pi \sqrt{\frac{4}{9}} = 6\pi \times \frac{2}{3} = 4\pi \] Therefore, the phase shift constant of medium B is \( 4\pi \), which corresponds to option A \( 6\pi \).
The correct sequence is:
B, A, D, C